writing special provisions for frp strengthening...
TRANSCRIPT
Gregg Blaszak, P.E.Milliken Infrastructure Solutions, LLC
Writing Special Provisions for FRP Strengthening Projects
• FRPs are externally bonded to or wrapped around existing concrete or steel members to increase their strength or seismic performance.
• FRPs are used where additional rebar or steel plates are desired.
• FRPs compete with many strengthening techniques but are often the most attractive solution.
Introduction to FRP Strengthening Systems
The Basics
Introduction to FRP Strengthening Systems
Common Strengthening Forms
Unidirectional Fabrics Multi-directional Fabrics• Bi-directional (0/90)• Bi-Ax (± 45)
Pre-cured FRPs• Strand Sheets• CFRP Plates
NSM• CF Bars• CF Tapes
How DOT’s Use FRP Strengthening Systems
Pier Column Strengthening
How DOT’s Use FRP Strengthening Systems
Pier Cap Strengthening
How DOT’s Use FRP Strengthening Systems
Girder Strengthening
CFRP U-wraps used for shear strengthening of concrete girder
How DOT’s Use FRP Strengthening Systems
AASHTO Girder Repairs
How DOT’s Use FRP Strengthening Systems
Deck Strengthening
Negative moment strengthening of deck slab using CF Bars installed in NSM slots
How DOT’s Use FRP Strengthening Systems
Deck Strengthening
NSM Strengthening of cantilevered portion of deck to accommodate new barrier and higher forces
How DOT’s Use FRP Strengthening Systems
Arch Slab Strengthening
How DOT’s Use FRP Strengthening Systems
Protection, Spall Repair Confinement
How DOT’s Use FRP Strengthening Systems
Steel Member Strengthening
How DOT’s Use FRP Strengthening Systems
Steel Member Strengthening
UHM CFRP Strand Sheets used to restore lost cross-section
Structural Applications• Pier Caps• Pier Columns• Girders• Decks• Piling• Steel Members
Non-Structural Applications• Spall confinement• Waterproofing
How DOT’s Use FRP Strengthening Systems
Conclusions
FRP Design Basics
FRP Design Basics
Material Properties
0
100
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700
0.000 0.010 0.020 0.030 0.040 0.050 0.060
Tensile Strain (in./in.)
Ten
sile
Str
ess
(ks
i) Carbon
Aramid
Glass
Comparison of the Tensile Strength of the Fibers
UHMCarbon
FRP Design Basics
Material Properties
0
100
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0.000 0.010 0.020 0.030 0.040 0.050 0.060
Strain (in/in)
Str
ess (
ksi)
Carbon Fiber
Steel Strand
Steel Rebar
Tensile Behavior of Construction Reinforcements
• Most bond applications are controlled by…– FRP rupture– Concrete failure– Debonding of FRP
• The more layers of FRP used, the more likely debonding will control
• The more layers of FRP, the less efficient each layer becomes
• Increasing FRP stiffness lowers the effective strain of the FRP
FRP Design Basics
Flexure
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
0 600000 1200000 1800000 2400000 3000000
n tf Ef (lbs/in)
k m
Effect of FRP Stiffness on Effective Strain
FRP Design Basics
Shear
Fully WrappedU-wrapTwo-sides
GOOD BETTER BEST
• Most bond applications are controlled by…– Debonding of FRP– Concrete shear failure
• Strain in FRP is limited to 0.004 to prevent loss of aggregate interlock
• The more layers of FRP used, the more likely debonding will control
• The more layers of FRP, the less efficient each layer becomes
• Increasing FRP stiffness lowers the effective strain of the FRP
FRP Design Basics
Shear
Effect of FRP Stiffness on Effective Strain
0
0.05
0.1
0.15
0.2
0.25
0.3
0.35
0.4
0 0.013 0.026 0.039 0.052 0.065
Af(in2)
kv
• Fibers oriented transverse to the longitudinal axis of the member
• Results in an increase in the apparent strength of the concrete and in the maximum usable compressive strain in the concrete
• Passive confinement: Intimate contact between FRP system and member is critical
• Improves ductility of column
• Practical limit is based on service stress
• Strain in FRP is limited to 0.004 to guard against shear failure
FRP Design Basics
Axial Enhancement
0
1000
2000
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7000
8000
0 0.005 0.01 0.015 0.02 0.025
Strain (in/in)
Str
ess (
psi)
Circular
Square
Rectangular (1:2)Unconfined
Compression Behavior of FRP Confined Concrete
Specifying and Detailing
• Design guide for concrete strengthening since 2002
• 2017 edition includes seismic provisions
• Emphasis on buildings
• Includes provisions for NSM strengthening
• Limited info on anchors
• Technote to address confusion surrounding the UL-Listings for fire
Sources of Information
ACI 440.2R-17
• Similar to ACI 440.2R
• Includes design equations for flexure, shear/torsion, and axial strengthening
• Designs made with AASHTO are different from those made with ACI 440 (BEWARE)
• Never specify both ACI 440 and AASHTO guides on a project!
Sources of Information
AASHTO Guide Specification
• Peeling requirement appears more
academic than practical
• Cannot be quantified in practice
• Suppliers do not report shear modulus
values of the resin
• Bond line thickness (while important) is not
measured or controlled in the field.
• How to QC this?
Sources of InformationAASHTO Guide Spec
Sources of Information
AASHTO vs. ACI
• ICRI 330 Committee composed entirely of engineers, contractors, and material suppliers.
• Based largely on the contents of the ACI 440.2R guide and the collective experience of committee members
• It’s a special provision for buildings!
• Covers fabric FRP systems (NSM soon to be released)
Sources of Information
ICRI Guide 330.2-2016
1. Condition survey
2. Analyze structure and determine members/sections that require strengthening
3. Determine if FRP is feasible
4. Design FRP
5. Shop drawings and specifications
6. Review submittals
7. Inspect installation
Phases in a Typical Project
• EOR will nearly always be responsible for the condition assessment and analysis of the structure
– Design-build projects are more unique
• Determine location and magnitude of deficiencies
• Verify if FRP can be used
• Determine who will be responsible for FRP design (EOR or Contractor)
• Prescriptive or performance special provision?– Most projects combine performance and prescriptive elements
• Where will information be communicated (drawing notes, special provision)
Structural Analysis Phase – Role of EOR
Structural Analysis Phase – Role of EOR
1) Verify if FRP can be used before specifying
Unstrengthened member checks:• ACI 440.2R: 𝜙𝑅𝑛 𝑒𝑥𝑖𝑠𝑡𝑖𝑛𝑔 ≥ 1.1𝐷𝐿 + 0.75𝐿𝐿 𝑛𝑒𝑤
• AASHTO: 𝑅𝑟 𝑒𝑥𝑖𝑠𝑡𝑖𝑛𝑔 ≥ 𝜂𝑖 (𝐷𝐶 + 𝐷𝑊) + (𝐿𝐿 + 𝐼𝑀) 𝑛𝑒𝑤
(Guards against over-strengthening and collapse if FRP fails)
2) Is application bond-critical or contact-critical?• Impacts design, detailing, installation and inspection• f’c > 2000 psi for bond-critical
• FRP special provision is part of a large project manual– Project manual includes specifications on
concrete repair, crack injection, etc.
• FRP requirements are shown as part of the general notes on the plans
• Drawing notes accompanying the FRP details
Where to Communicate FRP Requirements?
EOR designs FRP system
• On plans, EOR provide all details of FRP system– Number of plies– Ply width– Ply orientation– Anchors
• EOR specifies an acceptable FRP product(s) or minimum properties
• Contractor submits products meeting specification– Sealed calculations/shop drawings usually not
required
Prescriptive Specifications
Commonly used for non-structural applications like confinement of spalls or protection where no design calculations are made
EOR defines performance requirements and Contractor designs FRP system
• EOR specifies requirements at sections to be strengthened
• EOR provides all necessary information at sections to be strengthened to complete FRP design.
• EOR specifies minimum properties of FRP system
• EOR requires contractor to submit product data, design calculations and shop drawings
• If details are unknown, EOR needs to provide guidance
Performance Specifications
Used on the majority of all FRP projects, especially structural applications
1) Provide FRP equivalent to calculated additional rebar– For example, provide FRP equivalent to #5 @ 12 o.c.– Must require FRP design to be based on effective strain per ACI 440 and include FRP reduction
factors (Ce, yf)
2) Specify strengths to be provided by FRP (yf Mf, yf Vf, etc.)– Include all information to make a design (dimensions, rebar layout, etc.)
3) Specify desired member strengths (fMn, fVn, etc.)– Include all information to make a design (dimensions, rebar layout, etc.)– Include unfactored dead and live loads to do service checks
Specifying the Member Requirements
• Location of all sections to be strengthened
• Dimensions of existing sections and framing plan
• Sufficient dimensions to be able to do a take-off
• Existing reinforcement layout and grade
• Existing concrete strengths
• Be careful when including quantities in bill of material– Coverage area (1 ply) or area of material
Required Information for Performance Specifications
Include all the information used to determine their was a deficiency.
The FRP Engineer will need to design the FRP
• Only require submittals that will be reviewed
• Product technical data sheets
• Select test reports, installation guides, SDS, etc.
• Shop drawings – Needed for performance specifications
• Engineering calculations– Make sure they are really required– May be needed to show products meet minimum requirements or equivalency
• Avoid requiring sealed drawings/calculations to be submitted with bid.
Specifying the General Requirements
Submittals
PAYMENT BASIS• Lump sum is common and should cover all
materials, labor, equipment work to complete the job
• Unit price basis may be used.– Normally SF of coverage area, not SF of
material area
• Bid Tabulations– Be careful about comparing unit prices from
job to job – highly dependent on number of layers, surface prep, etc.
• Avoid exotic units
WARRANTY• Majority of projects require 1 year warranty
on materials and installation– Manufacturer warrants materials– Contractor warrants installation
• Avoid unreasonable warranties which will…– Unnecessarily raise project cost– Invite “desperate” suppliers and installers to
“roll-the-dice”
• Avoid subjective language like…– “FRP system shall be designed to last 50 years”
Specifying the General Requirements
Payment Basis and Warranty
Features of a typical TDS
• Typical vs. design properties
• “Fiber” properties
• Laminate/design properties
• Are unit values for strength/modulus reported?
• Where is ply thickness specified?
• AASHTO requires minimum 1% design elongation
Specifying the Materials
Understanding Technical Data Sheets
Typical Fabric and Fiber Properties
• NEVER USE FOR DESIGN!
• Intended to convey the grade of fiber used in fabric and fabric weight
• ACI 440 recognizes FRP systems that report properties using the “Net Fiber Area” method where the ply thickness is calculated based on the area of the fibers.
Specifying the Materials
Understanding Technical Data Sheets
Mechanical and Physical Properties
• Make sure they are “design” properties.
• Modulus is reported as an average value.
• Avoid FRP systems that require you to call to get the design properties
• Typical values may be reported for Tg and other physical properties
Specifying the Materials
Understanding Technical Data Sheets
• Normalized tensile strength/stiffness in terms of kips/inch/ply.
• Allows properties of any FRP system to be compared or accepted/rejected as equivalent.
• Calculated as follows:– 𝑈𝑛𝑖𝑡 𝑆𝑡𝑟𝑒𝑛𝑔𝑡ℎ = 𝑡𝑓 × 𝑓𝑓𝑢
∗ (kips/inch/ply)
– 𝑈𝑛𝑖𝑡 𝑆𝑡𝑖𝑓𝑓𝑛𝑒𝑠𝑠 = 𝑡𝑓 × 𝐸𝑓 (kips/inch/ply)
• All manufacturers should report unit tensile values on their TDS
• Most important design property is unit stiffness (Et) since all applications limit the strain in the FRP
Specifying the Materials
Unit Tensile Properties
Always specify the following:
• Min. unit tensile strength (kips/inch/ply)• Min. unit tensile modulus (kips/inch/ply)• Min. rupture strain (%)
OR
• Min. tensile strength (ksi)• Min. tensile modulus (ksi)• Min. rupture strain (%)• Ply thickness (inch)
• DO NOT specify minimum mechanical properties of the resin– The resin properties are not used in design equations
• DO require the FRP system and all it’s constituent materials be tested together as a system.
• BE CAREFUL about allowing field thickening of resins – Thickening epoxy using Cab-o-Sil is fairly common practice– Adding filler to epoxy weakens and makes it brittle.– Better to specify lighter weight fabrics than allowing field thickening
• DO NOT over specify properties – you could end up with no product meeting spec!
Specifying the Materials
Specify Resin Properties?
• Include minimum Tg of 140 F. Most FRP systems can meet this temperature requirement.
• Durability testing– CALTRANS requires 10,000-hr exposure tests
• Require ICC-ES Reports?– ICC-ES evaluates products for “compliance” with an acceptance criteria and the
building code.– Maybe. Almost universally required on the West Coast.– At a minimum, require the durability testing outline in AC 125
Specifying the Materials
Additional Requirements
• Wet Lay-up Method
– Used for fabric FRP systems
– Roller application “Dry Lay-up”
– Pre-Saturation
– Impregnating machine
• Secondarily Bonded
– Used for pre-cured FRP systems (NSM)
Specifying the Installation
FRP Installation Techniques
1) Repair substrate (Inject cracks, repair spalls, fill voids, etc.)
2) Prepare substrate surface (sand-blast, grind, water-blast, round corners, etc.)
– Is application bond-critical or contact-critical?
3) Install FRP system (wet or dry lay-up)
4) Remove air voids
5) Allow FRP system to cure
6) Inspect cured system
7) Paint/coat FRP
Specifying the Installation
General Installation Procedure
• Substrate repairs are not included in the FRP special provision
• Many of the installation methods are “in accordance with manufacturer’s recommendations”
• Temperature/Humidity– Resin working time– Resin cure time– Moisture vapor transmission (MVT)– Storage of materials
• May need to ice resins or heat tented area using clean heat source
• In case of MVT, may need to install at night as temperature is falling
• Wet surfaces
• Age/cure of patching materials
Specifying the Installation
Installation Considerations
Specify the following:
• Temperature range FRP may be installed
• Minimum age/strength of patching materials (Avoid 28 days)
• Bond-Critical– Make repairs first– Grit-blasting or other means to achieve ICRI
CSP-3 or higher– Surface needs to be flat– Round corners (for U-wraps)– Clean surface
• Contact-Critical– Round corners to ½” radius– Surface profile needs to promote continuous
contact– Remove paint or other coatings?– Clean surface
Specifying the Installation
Surface Preparation
• Wet lay-up or “dry lay-up”– Refers to whether a machine is used to
wet out the fabric
– Heavier weight fabrics will usually require a machine to wet them out
– Specify that fabrics should be wet out in accordance with manufacturer’s instructions
Specifying the Installation
Application of the FRP
• Material certificates of conformance
• Daily reports (what was installed, where, temperature, etc.)
• Tensile tests (witness panels)
• Fabric alignment (< 1”/foot deviation)
• Delaminations
• Cure of resins
• Adhesion strength (for bond-critical)
Specifying the QC Inspections
General Requirements
For any inspection tests, minimum acceptance criteria need to be provided.
Specifying the QC Inspections
Inspection Requirements
Inspection
Bond-Critical Contact-Critical
Structural Protection Structural Protection
Visual X X X X
Sounding X X X X
Adhesion Testing X X
Witness Panels X X
• Witness panels are fabricated and cured in the field from the same materials (fabrics and resin) used on the project
• Analogous to concrete cylinders
• Panel quality varies widely and is challenging to get good test results
• Usually one per day per crew or 5,000 SF of material installed
• Test per ASTM D7565 and report unit tensile values
• Proposed acceptance criteria:– Individual tensile strength > reported design value– Average modulus > 90% reported value
Specifying the QC Inspections
Witness Panels
• Not uncommon
• Found visually or by acoustic sounding (tap testing)
• Suggested frequency of 1 tap per 0.5 SF
• Outline of delaminations should be marked
• Acceptance Criteria:– Small delaminations (<2 in2) are OK provided they…
• do not exceed 5% of total area • there are not more than 10 per 10 SF area
– Large delaminations (>25 in2) need to be cut out
– Mid-size delaminations (>2 in2 and <2 in2 ) may be repaired by epoxy injection
Specifying the QC Inspections
Delaminations/Voids
• Only for bond-critical Applications
• ASTM D7522
• Suggested frequency of one per day per crew or one per 1,000 SF of contact area
• Acceptance criteria:– Strength > 200 psi– Ideally, failure in the substrate– Failures not in substrate are reported to engineer
Specifying the QC Inspections
Adhesion Strength
• DO analyze structure
• DO determine if FRPs are an appropriate method
• DECIDE on prescriptive or performance
• ALWAYS specify unit tensile values (or tensile properties + ply thickness)
• INCLUDE all section details for performance specifications
• INCLUDE detailed FRP design values for prescriptive specifications
• DO NOT over specify properties
• CONTINUE to use FRPs with confidence!
Concluding Remarks
Gregg Blaszak, P.E.Milliken Infrastructure Solutions, LLC
THANK YOU!